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Looking at the Haskell documentation, lifting seems to be basically a generalization of fmap, allowing for the mapping of functions with more than one argument.

The Wikipedia article on lifting gives a different view however, defining a "lift" in terms of a morphism in a category, and how it relates to the other objects and morphisms in the category (I won't give the details here). I suppose that that could be relevant to the Haskell situation if we are considering Cat (the category of categories, thus making our morphisms functors), but I can't see how this category-theoretic notion of a lift relates the the one in Haskell based on the linked article, if it does at all.

If the two concepts aren't really related, and just have a similar name, are the lifts (category theory) used in Haskell at all?

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1 Answer 1

up vote 17 down vote accepted

Lifts, and the dual notion of extensions, are absolutely used in Haskell, perhaps most prominently in the guise of comonadic extend and monadic bind. (Confusingly, extend is a lift, not an extension.) A comonad w's extend lets us take a function w a -> b and lift it along extract :: w b -> b to get a map w a -> w b. In ASCII art, given the diagram

        w b
         |
         V
w a ---> b

where the vertical arrow is extract, extend gives us a diagonal arrow (making the diagram commute):

     -> w b
    /    |
   /     V
w a ---> b

More familiar to most Haskellers is the dual notion of bind (>>=) for a monad m. Given a function a -> m b and return :: a -> m a, we can "extend" our function along return to get a function m a -> m b. In ASCII art:

a ---> m b
|
V
m a

gives us

a ---> m b
 |  __A
 V /
m a

(That A is an arrowhead!)

So yes, extend could have been called lift, and bind could have been called extend. As for Haskell's lifts, I have no idea why they're called that!

EDIT: Actually, I think that again, Haskell's lifts are actually extensions. If f is applicative, and we have a function a -> b -> c, we can compose this function with pure :: c -> f c to get a function a -> b -> f c. Uncurrying, this is the same as a function (a, b) -> f c. Now we can also hit (a, b) with pure to get a function (a, b) -> f (a, b). Now, by fmaping fst and snd, we get a functions f (a, b) -> f a and f (a, b) -> f b, which we can combine to get a function f (a, b) -> (f a, f b). Composing with our pure from before gives (a, b) -> (f a, f b). Phew! So to recap, we have the ASCII art diagram

  (a, b) ---> f c
    |
    V
(f a, f b)

Now liftA2 gives us a function (f a, f b) -> f c, which I won't draw because I'm sick of making terrible diagrams. But the point is, the diagram commutes, so liftA2 actually gives us an extension of the horizontal arrow along the vertical one.

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+1 for making me chuckle at how little I understood of this answer on the first, second and third passes. The ASCII diagrams make it, IMHO. –  Tom W Jul 21 '14 at 11:19

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